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Introduction to the Introduction to the Standard ModelStandard Model
Quarks and leptons
Bosons and forces
The HiggsBill Murray,
RAL,
March 2002
2
Outline:Outline:
An introduction to particle physics
What is the Higgs Boson?Some unanswered questions
3
From you to the quarkFrom you to the quark
Electrons orbiting nucleus
d type quark
u type quarks
4
d
The Matter ParticlesThe Matter Particles
e
Neutrino
Electron
ProtonMass: 1.7 10-27 kg
charge: +1
Mass: ~<10-9 proton mass?Charge: 0
Mass: 0.0005 proton mass charge: -1
u
ud
Neutron Charge: 0ud
5
How do we know about quarks? How do we know about quarks?
Stanford Linear Accelerator Centre, California
Fire electrons at protons: See big deflections!
Rutherford found a nucleus in the atom by firing alpha particles at gold and seeing them bounce back
Late 1960’s
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The particles of Matter The particles of Matter
e
‘up’ quark
neutrino
e
u
d
Electron
‘down’ quark
uu
dd
Come in 3 versions, known as colours
Exercise to check this later
Why 3 colours
?
7
The particles of MatterThe particles of Matter
e
u
d
e
All ordinary matter is composed of these
(There is a corresponding antiparticle for each)
See Stefania’s talk later
8
The Matter particlesThe Matter particles
u
d
e
1st Generation
Ordinary matter
2nd Generation
Cosmic rays
s
c
3rd Generation
Accelerators
b
t
Why 3 generation
s?
9
The Matter particlesThe Matter particles
e
u
d
e
1st Generation
2nd Generation
s
c
3rd Generation
b
t
0.1GeV
1.7GeV
4.5GeV
175GeV
E=mc2
1GeV~Proton Mass
1.7GeV
Others are lighter
10
The Matter particlesThe Matter particles
u
d
e
1st Generation
2nd Generation
s
c
3rd Generation
b
t
1974
1977
2000 1995
19751897
11
How do quarks combine?How do quarks combine?
u
ud
A proton:
two ‘u’ quarks and one ‘d’ quark
d
ud
A neutron:
2 ‘d’ quarks and 1 ‘u’ quark
u
d
Mesons have a quark and an anti-quark-
Many created, not stable
With 6 quark types there are
hundreds of combinations
12
Can we see a quark? Can we see a quark?
Probably not
The picture shows the result of making a pair of quarks at
LEP, CERN
The quarks are not seen: A jet of
‘hadrons’ is instead
13
+
Forces in Ordinary PhysicsForces in Ordinary PhysicsClassically, forces are described by
+
Field
charges and fields
++
14
Continuous field exchange of quanta
+ +
For Electromagnetism
The quanta are photons,
High energies and small distances quantum mechanics
Forces in Particle PhysicsForces in Particle Physics
15
The Forces of NatureThe Forces of Nature
Force Realm Particle
Electro-magnetism
Magnets, DVD players
Strong Fusion Gluon
Weak -decay, (sunshine)
W+,W-, Z0
Gravitation Not in the same framework
Higgs may give a link?
16
The Forces of NatureThe Forces of Nature
Force Mass, GeV Particle
Electro-magnetism
0
Strong 0 Gluon
Weak
W’s Z
Gravitation Not in the same framework
17
Feynman Diagram
Positron (anti-electron)
Mediation of the ForcesMediation of the Forces
Electron
At each ‘vertex’ charge is
conserved. Heisenberg Uncertainty
allows energy borrowing.
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Particles and forcesParticles and forces
‘u’ quarks ‘d’ quarks electron neutrino
E.M.charge
+2/3
Strongforce
yes yes no no
Weakforce
yes yes yes yes
Heavier generations have identical pattern
19
What is the Higgs boson?What is the Higgs boson? The equations describing the forces and
matter particles work well. Unfortunately they demand that they all
weigh nothing– We know this is not true
Prof. Higgs proposed an addition which corrects this.
Together Known as…
The Standard The Standard ModelModel
20
The Waldegrave Higgs challengeThe Waldegrave Higgs challengeIn 1993, the then UK Science Minister,
William Waldegrave, issued a challenge to physicists to answer the questions:
'What is the Higgs boson, and why do we want to find it?’
on one side of a sheet of paper.
David Miller of UCL won a bottle of champagne for the following:
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The Waldegrave Higgs challengeThe Waldegrave Higgs challenge
Imagine a room full of political activists
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The Waldegrave Higgs challengeThe Waldegrave Higgs challenge
The Prime Minister walks in
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The Waldegrave Higgs challengeThe Waldegrave Higgs challenge
He is surrounded by a cluster of people
Analogous to generation of Mass
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The Waldegrave Higgs challengeThe Waldegrave Higgs challenge
Imagine the same room again
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The Waldegrave Higgs challengeThe Waldegrave Higgs challenge
A interesting rumour is introduced
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The Waldegrave Higgs challengeThe Waldegrave Higgs challengeThanks to D. Miller
and CERN
Soon we have a cluster of people discussing it
Analogous to Higgs boson
© PhotoCERN
27
What does Higgs theory imply?What does Higgs theory imply?
Higgs’ mechanism gives mass to W and Z bosons,
and to the matter particles.
Mass of the W predicted
We can check it
The Higgs Boson mass is not predicted
It also predicts one extra particle:
The Higgs boson
28
The W, the top quark and HiggsThe W, the top quark and Higgs
We can calculate the mass of the W boson
Need the mass of the Z and the strength of the forces; these are well known
It is also affected by:– Top quark mass: Weak effect
– Higgs mass: Tiny effect
29
The W, the top quark and HiggsThe W, the top quark and Higgs
The W mass is about 80GeV/c2
30
The W, the top quark and HiggsThe W, the top quark and Higgs
Expanded scale
The W mass depends upon the
top and Higgs masses
31
CERN’s Collider ringCERN’s Collider ring
LEP : e+e-, Ecms~ 210 GeVLHC : pp, Ecms~ 14000 GeV
CERN
4 LEP experiments: 2 LHC experiments
DELPHI
© PhotoCERN
32
What are LEP and LHC?What are LEP and LHC?LEP LHC
Beams of Electrons Protons
Energy, GeV 208 14,000
Max. Higgs Mass
115 ~1000
Detailed? Yes No
Operation 1989-2000 2006-
Complementary machines – but needing the same tunnel
Work started 1980’s
33
In the LEP tunnelIn the LEP tunnel
27km of vacuum pipe and bending magnets
© PhotoCERN
34
Now to be the LHC tunnelNow to be the LHC tunnel
27km of vacuum
pipe
8.3Tesla bending magnets,
3o above absolute
zero
© PhotoCERN
35
One experiment: ‘OPAL’One experiment: ‘OPAL’
One of four
rather similar
detectors
Assembly in 1989Note the people
© PhotoCERN
36
An LHC experiment: ATLASAn LHC experiment: ATLAS
In constructionNote the people
© PhotoCERN
37
Z studies at LEPZ studies at LEPFrom 1989 to 1995
LEP created 20,000,000 Z bosons
These were used for detailed studies of its
properties Here you see the analysis which
established the number
of neutrinos as 3
They can say something about the
Higgs too.
Rat
e
Peak at Z mass, 91GeV
38
Positron
Feynman Diagram for Z productionFeynman Diagram for Z production
Electron
Z Cannot see the Z
Only its decay products
39
IndirectIndirect Search for the Higgs Boson Search for the Higgs Boson
Basic Feynmandiagram
top
Properties of the Z boson changed by ‘loop’ effects:
Higgs
What is affected?
Z decay rate to b’s - sensitive to top mass
Angular distributions - sensitive to W & H mass
40
IndirectIndirect Search for the Higgs Boson Search for the Higgs Boson
%1
%1
0.1% Precision needed!
By carefully studying Z’s we:• Predict mtop and mW;
Compare with measurements;• Predict mH;
Compare with measurements.
top
Higgs
41
How to recognize Z decays:How to recognize Z decays:e) Z->-
Z qq: Two jets, many particles
Z e+e-, -: Two charged particles (e or .)
Z -: Each gives 1 or 3 tracks
-
42
How to recognize Z decays:How to recognize Z decays:e) Z->-
Z bb:: Like qq events, with detached vertices, Like qq events, with detached vertices, measured in accurate vertex detectorsmeasured in accurate vertex detectors
Z : Not detectable. -
--
-
(weak and slow decaysto lighter quarks)
43
One example Z distribution:One example Z distribution:ZAngular distributionsAngular distributions
•This distribution depends on the W mass DELPHI
1993-199546GeV
45GeV
47GeV
Many things are used:
Z mass,
Several angular distributions,
Z decay fraction to bb Cos() of outgoing
Ra t
e of
oc c
urr
e nc e
44
The W, the top quark and HiggsThe W, the top quark and Higgs
The W and top masses from Z studies agree with theory
i.e. they lie on the curves
Result from Z studies
They can be checked by
direct measurement
45
The W, the top quark and HiggsThe W, the top quark and Higgs
W mass from LEP and Tevatron
Completely consistent!
This suggested the top quark had a mass of 175GeV
before it had been discovered
46
The W, the top quark and HiggsThe W, the top quark and Higgs
Top mass from
Tevatron
Again, incredible
consistency
The top mass directly measured agrees completely with the predicted
one
47
The W, the top quark and HiggsThe W, the top quark and Higgs
Scale has been
expanded further
The data (especially if they
are averaged) suggest a Higgs
mass around 100GeV
This procedure worked for the top quark. Will it work
again?
10GeV 100GeV
1000GeV
48
Summary of modelSummary of modelW mass agrees with Higgs theory
– to 1 part in 1000Electro-weak corrections verified:
– W mass agrees with prediction– Top mass agrees with prediction
Higgs mass should be:
GeV543485
49
The Search for the HiggsThe Search for the HiggsIn the late 1990’s ‘LEP’ at CERN ran
with enough energy to make W pairsThere was also hopes it might make
a Higgs.
50
The W pairs: The W pairs:
W’s produced by reactions like this one
Each W decays in ~10-26 seconds
Or quarks (2 sorts)
e-,
e
Into leptons (3 sorts)
51
WW++WW--: What do we see?: What do we see?
A muo
n
An electron
Both W’s decayed to leptons
52
WW++WW--: What do we see?: What do we see?
A quark
A jet from a quark
A muon
One W as 2 quarks, the other as leptons.
The nicest signature
53
WW++WW--: What do we see?: What do we see?
A jet from a quark
A quark
A quark
A quark
Both W’s decayed to 2
quarks
54
How could LEP make a Higgs ?How could LEP make a Higgs ?
Make a Higgs and a Z together
So need Energy greater than Higgs mass plus Z mass
Predicted LEP events, 4 experiments
55
tau
b quarks
gluons
WW
other
Higgs and Z decay channelsHiggs and Z decay channels
Higgs decay modes
taus
quarks
neutrinos
electrons
muons
Z decay modes
e.g. ZHbb All Z decay modes used
Higgs only into b-quarks
B quarksAny quark
WW
Recall: Both Z & H are made
56
First data above 206 GeV:First data above 206 GeV: First Serious Candidate (14-Jun-2000, 206.7 GeV)
• Mass 114.3 GeV/c2;Mass 114.3 GeV/c2;• Good HZ fit;Good HZ fit;• Poor WW and ZZ fits;• P(Background) : 2%P(Background) : 2% • s/b(115) = 4.6s/b(115) = 4.6
The purest candidate event ever!
b-tagging (0 = light quarks, 1 = b quarks)
• Higgs jets: 0.99 and 0.99;
• Z jets: 0.14 and 0.01.
e+e- bbqq_ _
MissingMomentum
High pT muon
58
Combined Mass PlotCombined Mass PlotDistribution of
the reconstructed Higgs boson mass with
increasing purity for a signal with mass 115 GeV/c2
Essential to understand the
background if we want to claim
something new
Yellow: background
Red: Higgs
59
What is the position?What is the position?
We look to the future to solve this question.
LEP closed in 2000
mH 53 to 141 GeV/c2
mH = 115.6 GeV/c2- 0.8+ 0.8
•Precision studies of Z,W and top DEMAND a Higgs:•MW agrees with Higgs’ predictions to 1 per mille,
• Direct Searches (4 in 100 effect)
Is this a coincidence?
60
What happens next?What happens next?
s = 2000 GeVs = 2000 GeV
The Tevatron:
• A pp collider, near Chicago;
• run II started in 2001 – collecting
far more data than before
•Can probably find a 115GeV
Higgs by 2007
61
What happens next?What happens next?
The LHC:
• CERN’s future pp collider;
• Designed to find the Higgs, it
can do it!
•First chance in 2007
s = 14000 GeVs = 14000 GeV
62
What happens next?What happens next?
TESLA:
• A Proposed e+e- collider -
CLEAN
• 500-800GeV, very high
rate
•Find the Higgs in ½ a
day: study it carefully
s = 800 GeVs = 800 GeV
63
Some Unanswered QuestionsSome Unanswered Questions Does the Higgs exist? If not, how do you
explain mass? Where is all the anti-matter?
– See Stefania’s talk
What about Gravity– Why do we get the cosmological constant
wrong by 10120?
Why are there 3 generations of particles? And 3 colours?
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